Oil pressure control apparatus

ABSTRACT

In one embodiment, an oil pressure control apparatus includes a belt-driven continuously variable transmission, a lockup clutch provided in a torque converter, a primary regulator valve that regulates a line oil pressure that becomes a source pressure of oil pressure of various parts, and a clamping oil pressure control valve that supplies a clamping oil pressure to a driven-side pulley of the belt-driven continuously variable transmission. Control of the primary regulator valve is performed with a control oil pressure of a linear solenoid valve that controls the clamping oil pressure control valve, and a control oil pressure of a linear solenoid valve that controls engagement/release of the lockup clutch.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority under 35 U.S.C. §119(a) on Japanese Patent Application No. 2007-234593 filed in Japan on Sep. 10, 2007, the entire contents of which are herein incorporated by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to an oil pressure control apparatus of a vehicle power transmission apparatus.

2. Description of the Related Art

As a power transmission apparatus provided in a vehicle, a power transmission apparatus is known that has a belt-driven continuously variable transmission in which a belt is clamped with oil pressure to transmit motive power, and the gear ratio is changed by changing the belt contact radius, a hydraulic friction engaging element for travel (for example, a forward movement clutch) that is engaged in order to establish a motive power transmission path when the vehicle travels, and a hydraulic lockup clutch that is provided in a hydrodynamic motive power transmission apparatus provided in the motive power transmission path and directly couples a motive power source side and the belt-driven continuously variable transmission side.

In an oil pressure control apparatus of this sort of vehicle power transmission apparatus, many control valves of various types, electromagnetic valves that control those control valves, and the like are provided. For example, valves provided include a line oil pressure control valve that regulates a line oil pressure that becomes the source pressure for the oil pressure of various parts; a gearshift oil pressure control valve that regulates the line oil pressure that becomes the source pressure, and supplies a gearshift oil pressure that controls a gear ratio of the belt-driven continuously variable transmission to a driving-side pulley (primary pulley) of the belt-driven continuously variable transmission; a clamping oil pressure control valve that likewise regulates the line oil pressure that becomes the source pressure, and supplies a clamping oil pressure that controls belt clamping of the belt-driven continuously variable transmission to a driven-side pulley (secondary pulley) of the belt-driven continuously variable transmission; a garage control valve that can switch an engaging oil pressure, which is supplied when engaging the friction engaging element for travel, between an engaging transition oil pressure and an engagement holding oil pressure; and a lockup control valve that is switched when performing control to engage/release the lockup clutch. Also provided are linear electromagnetic valves, ON-OFF electromagnetic valves, or the like for controlling each of these control valves.

Conventionally, control of the line oil pressure control valve is performed with either one of two control oil pressures: the control oil pressure of a first linear electromagnetic valve that controls the clamping oil pressure control valve, and the control oil pressure of a second linear electromagnetic valve that controls engagement/release of the lockup clutch. Specifically, by switching an oil path according to engagement/release of the lockup clutch, the control oil pressure of either one of the linear electromagnetic valves is supplied to the line oil pressure control valve. In this case, the line oil pressure is controlled with the first linear electromagnetic valve when engaging the lockup clutch, and controlled with the second electromagnetic valve when releasing the lockup clutch. On the other hand, JP 2000-130574A discloses technology in which only control of the line oil pressure control valve is performed with a single linear electromagnetic valve.

Incidentally, when the control oil pressure of the linear electromagnetic valve drops due to a failure of the linear electromagnetic valve or the like, there is a possibility that a condition will occur in which the line oil pressure that becomes the source pressure is inadequate. As a result, on a low gear side where the gear ratio of the belt-driven continuously variable transmission is large, it is difficult to secure the clamping oil pressure necessary for belt clamping, so there is a possibility that belt slippage will occur.

When controlling the line oil pressure control valve by switching the oil path according to engagement/release of the lockup clutch as described above, in the case of engaging the lockup clutch and in the case of releasing the lockup clutch, the line oil pressure control valve is controlled with only respective independent linear electromagnetic valves, so there is a high possibility that the line oil pressure will be inadequate and thus belt slippage will occur.

On the other hand, when a dedicated linear electromagnetic valve that controls only the line oil pressure control valve is provided, the number of electromagnetic valves increases, resulting in increased size and cost of the apparatus.

SUMMARY OF THE INVENTION

It is an object of the present invention to provide an oil pressure control apparatus that is capable of appropriately controlling a line oil pressure, and with which it is possible to reduce the number of electromagnetic valves.

The invention provides an oil pressure control apparatus that includes a belt-driven continuously variable transmission in which a belt is clamped with oil pressure to transmit motive power, and a gear ratio is changed by changing a belt contact radius; a hydraulic lockup clutch provided in a hydrodynamic power transmission apparatus provided between a motive power source and the belt-driven continuously variable transmission, the lockup clutch directly coupling the motive power source side and the belt-driven continuously variable transmission side; a line oil pressure control valve that regulates a line oil pressure that becomes a source pressure of oil pressure of various parts; and a clamping oil pressure control valve that supplies a clamping oil pressure that controls a belt clamping pressure of the belt-driven continuously variable transmission to a driven-side pulley of the belt-driven continuously variable transmission; in which control of the line oil pressure control valve is performed with a control oil pressure of a first electromagnetic valve that controls the clamping oil pressure control valve, and a control oil pressure of a second electromagnetic valve that controls engagement/release of the lockup clutch.

According to the above configuration, a line oil pressure control valve and a clamping oil pressure control valve are controlled by a first electromagnetic valve, and the line oil pressure control valve and engagement/release of a lockup clutch are controlled by a second electromagnetic valve. Accordingly, it is possible to reduce the number electromagnetic valves by one in comparison to a case in which a line oil pressure control valve, a clamping oil pressure control valve, and engagement/release of a lockup clutch are controlled by respective dedicated electromagnetic valves. Thus, it is possible to avoid increases in apparatus cost and size.

Also, because the line oil pressure control valve is controlled by the first electromagnetic valve and the second electromagnetic valve, it is possible to suppress the occurrence of a condition in which the line oil pressure is inadequate, in comparison to a case in which the line oil pressure control valve is controlled by only an independent electromagnetic valve. That is, even assuming that one electromagnetic valve among the first electromagnetic valve and the second electromagnetic valve has failed, the line oil pressure control valve will be controlled by the other electromagnetic valve, so it is possible to suppress the occurrence of a condition in which the line oil pressure is inadequate, and thus it is possible to appropriately control the line oil pressure. Thus, even on a low gear side where the gear ratio of the belt-driven continuously variable transmission is large, it is possible to secure the clamping oil pressure necessary for belt clamping, and so it is possible to suppress the occurrence of belt slippage.

Here, when controlling the line oil pressure control valve and engagement/release of the lockup clutch with the second electromagnetic valve, it is preferable to provide a switching means (switcher) between the line oil pressure control valve and the second electromagnetic valve, the switching means being capable of switching between supplying the control oil pressure of the second electromagnetic valve to the line oil pressure control valve, and supplying the control oil pressure of the second electromagnetic valve to a lockup control valve that is switched when controlling engagement/release of the lockup clutch. This switching means is configured such that when engaging the lockup clutch, the control oil pressure of the second electromagnetic valve is supplied to the lockup control valve, and at other times, the control oil pressure of the second electromagnetic valve is supplied to the line oil pressure control valve.

A configuration may also be adopted in which when controlling the line oil pressure control valve and engagement/release of the lockup clutch with the second electromagnetic valve, the control oil pressure of the second electromagnetic valve is always supplied to the line oil pressure control valve, and supply of the control oil pressure of the second electromagnetic valve to the lockup control valve is controlled with a third electromagnetic valve.

Here, it is possible to control the line oil pressure control valve based on the higher control oil pressure among the control oil pressure of the first electromagnetic valve and the control oil pressure of the second electromagnetic valve. In this case, it is preferable that an acting area of the control oil pressure of the first electromagnetic valve on a spool of the line oil pressure control valve is the same as an acting area of the control oil pressure of the second electromagnetic valve on that spool. By adopting such a configuration, in the case of the line oil pressure control valve, without computing, for example, the control oil pressures of the first electromagnetic valve and the second electromagnetic valve, the higher oil pressure among the two control oil pressures is selected automatically, so it is possible to easily control the line oil pressure.

A configuration may also be adopted in which an acting area of the control oil pressure of the second electromagnetic valve on a spool of the line oil pressure control valve is larger than an acting area of the control oil pressure of the first electromagnetic valve on that spool. With this configuration, the force of the control oil pressure of the second electromagnetic valve that acts on the spool can be amplified in comparison to the force of the control oil pressure of the first electromagnetic valve that acts on the spool, so this configuration is effective from the standpoint that even when the control oil pressure of the second electromagnetic valve is low, it is possible to secure the necessary line oil pressure.

Furthermore, when a configuration is adopted in which the oil pressure control apparatus includes a hydraulic friction engaging element for travel (for example, a forward movement clutch) that is engaged in order to establish a power transmission path when a vehicle travels, it is preferable that when controlling an engagement transition in which the friction engaging element for travel is engaged, the control oil pressure of the second electromagnetic valve is supplied to the friction engaging element for travel, and other than when controlling that engagement transition, an engagement holding oil pressure that has been regulated with another system is supplied to the friction engaging element for travel. In this case, it is possible to adopt a configuration in which switching between the control oil pressure of the second electromagnetic valve that is supplied to the friction engaging element for travel, and the engagement holding oil pressure that is supplied to the friction engaging element for travel, is controlled with a fourth electromagnetic valve.

With this configuration, the line oil pressure control valve and the clamping oil pressure control valve are controlled by the first electromagnetic valve, and the line oil pressure control valve, engagement/release of the lockup clutch and the engagement transition of a friction engaging element for travel are controlled by the second electromagnetic valve. Accordingly, it is possible to reduce the number electromagnetic valves in comparison to a case in which the respective controls are performed by dedicated electromagnetic valves. Thus, it is possible to avoid increases in apparatus cost and size.

Alternatively, an oil pressure control apparatus according to the invention may be configured to include a belt-driven continuously variable transmission in which a belt is clamped with oil pressure to transmit motive power, and a gear ratio is changed by changing a belt contact radius; a hydraulic lockup clutch provided in a hydrodynamic power transmission apparatus provided between a motive power source and the belt-driven continuously variable transmission, the lockup clutch directly coupling the motive power source side and the belt-driven continuously variable transmission side; a hydraulic friction engaging element for travel that is engaged in order to establish a power transmission path when a vehicle travels; and a line oil pressure control valve that regulates a line oil pressure that becomes a source pressure of oil pressure of various parts; in which control of the line oil pressure control valve, control of engagement/release of the lockup clutch, and control of engagement transition oil pressure when engaging the friction engaging element for travel, are performed with one electromagnetic valve.

With the above configuration, control of the line oil pressure control valve, control of engagement/release of the lockup clutch, and control of the engagement transition of the friction engaging element for travel is performed by a single electromagnetic valve. Accordingly, it is possible to reduce the number electromagnetic valves in comparison to a case in which the respective controls are performed by dedicated electromagnetic valves. Thus, it is possible to avoid increases in apparatus cost and size.

Here, when controlling engagement/release of the lockup clutch with the electromagnetic valve, it is preferable that the line oil pressure control valve is controlled with another electromagnetic valve. In this case, it is possible to adopt a configuration in which the other electromagnetic valve controls a clamping oil pressure control valve that supplies a clamping oil pressure that controls a belt clamping pressure of the belt-driven continuously variable transmission to a driven-side pulley of the belt-driven continuously variable transmission. By adopting such a configuration, when controlling engagement/release of the lockup clutch with an electromagnetic valve, the line oil pressure control valve is controlled by another electromagnetic valve, so it is possible to suppress the occurrence of a condition in which the line oil pressure is not adjusted or a condition in which the line oil pressure is inadequate, and thus it is possible to appropriately control the line oil pressure. Thus, even on a low gear side where the gear ratio of the belt-driven continuously variable transmission is large, it is possible to secure the clamping oil pressure necessary for belt clamping, and so it is possible to suppress the occurrence of belt slippage.

According to the invention, in an oil pressure control apparatus, it is possible to reduce the number of electromagnetic valves, and furthermore, it is possible to suppress the occurrence of a condition in which line oil pressure is inadequate, and thus the line oil pressure is appropriately controlled.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows the schematic configuration of a vehicle drive apparatus according to an embodiment.

FIG. 2 is a block diagram that shows an example of a control system of a power transmission mechanism of the vehicle drive apparatus in FIG. 1.

FIG. 3 is a circuit diagram that shows an example of an oil pressure control circuit for controlling the power transmission mechanism of the vehicle drive apparatus in FIG. 1.

FIG. 4 shows changes in set values of a target gearshift oil pressure and a target clamping oil pressure according to a gear ratio of a belt-driven continuously variable transmission.

FIG. 5 shows part of an oil pressure control circuit that employs a primary regulator valve and has a configuration that differs from the configuration shown in FIG. 3.

FIG. 6 shows part of an oil pressure control circuit according to another embodiment.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows the schematic configuration of a vehicle drive apparatus according to an embodiment.

The example vehicle drive apparatus shown in FIG. 1 is preferably adopted in an FF (front engine/front drive)-type vehicle. This vehicle drive apparatus is provided with an engine (internal combustion engine) 10 that is a motive power source for travel, a torque converter 20, a forward/rearward switching apparatus 30, a belt-driven continuously variable transmission (CVT) 40, a deceleration gear apparatus 50, and a differential gear apparatus 60. In this vehicle drive apparatus, output of the engine 10 is transmitted from the torque converter 20 to the differential gear apparatus 60 via the forward/rearward switching apparatus 30, the belt-driven continuously variable transmission 40, and the deceleration gear apparatus 50, and distributed to left and right drive wheels 70L and 70R. A power transmission mechanism is configured with, for example, the torque converter 20, the forward/rearward switching apparatus 30, and the belt-driven continuously variable transmission 40.

The torque converter 20 is a hydrodynamic transmission apparatus that transmits motive power via a fluid, and is provided with a pump impeller 22 that is provided integrated with a front cover 21 to which an output shaft 11 of the engine 10 is linked; and a turbine runner 23 that faces the pump impeller 22, is provided adjacent to the inner face of the front cover 21, and is linked to the forward/rearward switching apparatus 30 via a turbine shaft 28. Specifically, the pump impeller 22 and the turbine runner 23 are provided with many blades (not shown), a spiral flow of the fluid is caused by rotation of the pump impeller 22, and by feeding that spiral flow to the turbine runner 23, torque is applied to cause the turbine runner 23 to rotate.

In a portion of the inner circumferential side of the pump impeller 22 and the turbine runner 23, a stator 24 is disposed that changes the flow direction of fluid that has been fed out from the turbine runner 23 so that the fluid flows into the pump impeller 22. The stator 24 is linked to a predetermined fixed portion via a unidirectional clutch 25. Also, the pump impeller 22 is provided with a mechanical oil pump (oil pressure source) 27 that, due to being rotationally driven by the engine 10, generates oil pressure in order to supply working oil to various parts of an oil pressure control circuit 100 (see FIG. 3).

The torque converter 20 is provided with a lockup clutch 26. The lockup clutch 26 is disposed in parallel with an actual torque converter configured from the pump impeller 22, the turbine runner 23, and the stator 24, and the lockup clutch 26 is held by the turbine runner 23 in a state facing the inner face of the front cover 21. The lockup clutch 26 is pressed against the inner face of the front cover 21 by oil pressure, and thus directly transmits torque from the front cover 21, which is an input member, to the turbine runner 23, which is an output member. Here, by controlling that oil pressure, it is possible to control the clutch amount of the lockup clutch 26. Specifically, the lockup clutch 26, by controlling a differential pressure (lockup differential pressure) ΔP of a lockup engaging oil pressure PON supplied to an engaging-side oil pressure chamber 261 and a lockup releasing oil pressure POFF supplied to a releasing-side oil pressure chamber 262 with a lockup control valve 140 of the oil pressure control circuit 100 (see FIG. 3), is completely engaged, half-engaged (engagement in a slipping state), or released.

By completely engaging the lockup clutch 26, the front cover 21 (pump impeller 22) and the turbine runner 23 rotate as a single body. Also, by engaging the lockup clutch 26 in a predetermined slipping state (half-engaged state), the turbine runner 23 rotates following the pump impeller 22 with a predetermined amount of slippage during driving. On the other hand, the lockup clutch 26 is released by setting the lockup differential pressure ΔP to a negative value. Engagement/release of the lockup clutch 26 by the oil pressure control circuit 100 will be described below.

The forward/rearward switching apparatus 30 is provided with a double pinion planetary gear apparatus 31, a forward movement clutch C1, and a rearward movement brake B1.

A sun gear 32 of the planetary gear apparatus 31 is linked together with the turbine shaft 28 of the torque converter 20, and a carrier 36 is linked together with an input shaft 47 of the belt-driven continuously variable transmission 40. The carrier 36 and the sun gear 32 are selectively linked via the forward movement clutch C1. A ring gear 33 is selectively fixed to a housing via the rearward movement brake B1.

Between the sun gear 32 and the ring gear 33, an inside pinion gear 34 that engages with the sun gear 32, and an outside pinion gear 35 that engages with the inside pinion gear 34 and the ring gear 33, are disposed. The pinion gears 34 and 35 are held by the carrier 36 such that they can rotate and revolve.

The forward movement clutch C1 and the rearward movement brake B1 are both hydraulic friction engaging elements for travel that are engaged/released with an oil pressure actuator. Due to the forward movement clutch C1 being engaged and the rearward movement brake B1 being released, a state is established in which the forward/rearward switching apparatus 30 rotates as one body, and in the forward/rearward switching apparatus 30, a forward motive power transmission path is formed. In this state, driving force in the forward direction is transmitted to the belt-driven continuously variable transmission 40 side. On the other hand, due to the rearward movement brake B1 being engaged and the forward movement clutch C1 being released, a rearward motive power transmission path is formed in the forward/rearward switching apparatus 30. In this state, the input shaft 47 rotates in a reverse direction relative to the turbine shaft 28, and this driving force in the rearward direction is transmitted to the belt-driven continuously variable transmission 40 side. When the forward movement clutch C1 and the rearward movement brake B1 are both released, the forward/rearward switching apparatus 30 is in neutral (a blocked state), in which motive power transmission between the engine 10 and the belt-driven continuously variable transmission 40 is blocked.

In more detail, the forward movement clutch C1 and the rearward movement brake B1 are engaged/released by a manual valve 170 of the oil pressure control circuit 100 (see FIG. 3) being mechanically switched according to operation of a shift lever 87 (see FIG. 2) are both hydraulic friction engaging elements for travel that are engaged/released with an oil pressure actuator. The shift lever 87, for example, is disposed to the side of a driver seat and is operated to switch by a driver. The shift lever 87 is selectively operated to shift positions such as a parking position “P” for parking, a reverse position “R” for rearward travel, a neutral position “N” that blocks motive power transmission, and a drive position “D” for forward travel. In the parking position “P” and the neutral position “N”, the forward movement clutch C1 and the rearward movement brake B1 are both released. In the reverse position “R”, the rearward movement brake B1 is engaged, and the forward movement clutch C1 is released. In the drive position “D”, the forward movement clutch C1 is engaged, and the rearward movement brake B1 is released. Engagement/release of the friction engaging elements for travel (the forward movement clutch C1 and the rearward movement brake B1) of the forward/reverse switching apparatus 30 by the oil pressure control circuit 100 will be described below.

The belt-driven continuously variable transmission 40 transmits motive power by clamping a transmission belt 45 with oil pressure, and changes the gear ratio by changing the belt contact radius of the transmission belt 45. The belt-driven continuously variable transmission 40 includes a driving-side pulley (primary pulley) 41 provided on the input shaft 47, a driven-side pulley (secondary pulley) 42 provided on an output shaft 48, and the transmission belt 45, which is made of metal and is wrapped around both of these pulleys 41 and 42. The belt-driven continuously variable transmission 40 is configured such that motive power is transmitted via frictional force between both pulleys 41 and 42 and the transmission belt 45.

The driving-side pulley 41 is a variable pulley whose effective diameter is variable, and is configured from a fixed sieve 411 that has been fixed to the input shaft 47, and a movable sieve 412 disposed on the input shaft 47 in a state in which the movable sieve 412 is slidable in only the axial direction. The driven-side pulley 42 likewise is a variable pulley whose effective diameter is variable, and is configured from a fixed sieve 421 that has been fixed to the output shaft 48, and a movable sieve 422 disposed in the output shaft 48 in a state in which the movable sieve 422 is slidable in only the axial direction. In the movable sieve 412 of the driving-side pulley 41, an oil pressure actuator 413 for changing a V channel width between the fixed sieve 411 and the movable sieve 412 is disposed. Likewise in the movable sieve 422 of the driven-side pulley 42, an oil pressure actuator 423 for changing a V channel width between the fixed sieve 421 and the movable sieve 422 is disposed.

In the belt-driven continuously variable transmission 40, by controlling an oil pressure (gearshift oil pressure) PIN of the oil pressure actuator 413 of the driving-side pulley 41, the V channel width of both pulleys 41 and 42 changes and thus the belt contact radius (effective diameter) of the transmission belt 45 is changed, so a gear ratio γ (=input shaft rotation speed NIN/output shaft rotation speed NOUT) changes continuously. Also, an oil pressure (clamping oil pressure) POUT of the oil pressure actuator 423 of the driven-side pulley 42 is controlled such that within a range that slippage of the transmission belt 45 does not occur, a predetermined belt clamping force (frictional force) that transmits transmission torque is generated.

The gearshift oil pressure PIN of the oil pressure actuator 413 of the driving-side pulley 41, and the clamping oil pressure POUT of the oil pressure actuator 423 of the driven-side pulley 42, are each regulated according to commands from an electronic control apparatus 80 (see FIG. 2). Here, the gearshift oil pressure PIN is controlled to regulate the pressure with a gearshift oil pressure control valve 120 of the oil pressure control circuit 100 (see FIG. 3). Also, the clamping oil pressure POUT is controlled to regulate the pressure with a clamping oil pressure control valve 130 of the oil pressure control circuit 100. Regulation of the gearshift oil pressure PIN and the clamping oil pressure POUT of the belt-driven continuously variable transmission 40 by the oil pressure control circuit 100 will be described below.

FIG. 2 is a block diagram that shows an example of a control system of a power transmission mechanism of the vehicle drive apparatus described above.

The electronic control apparatus 80 shown by way of example in FIG. 2 is provided with a CPU 801, a ROM 802, a RAM 803, and a backup RAM 804. The CPU 801 performs signal processing according to a program stored in advance in the ROM 802 while employing a temporary storage function of the RAM 803, and thus various controls are executed, such as control to regulate the gearshift oil pressure PIN and the clamping oil pressure POUT of the belt-driven continuously variable transmission 40, control of engagement/release of the friction engaging elements for travel (the forward movement clutch C1 and the rearward movement brake B1) of the forward/reverse switching apparatus 30, control of engagement/release of the lockup clutch 26 of the torque converter 20, and control to regulate a line oil pressure PL that becomes a source pressure of the oil pressure of various parts.

Described in more detail, various control programs, maps referred to when executing the various control programs, and the like are stored in the ROM 802. The CPU 801 executes computational processing based on the various control programs and maps stored in the ROM 802. The RAM 803 is a memory that temporarily stores the results of computational processing with the CPU 801, data input from various sensors, and the like, and the backup RAM 804 is a nonvolatile memory that stores data from the RAM 803 that should be saved when the engine 10 is stopped. Via a bidirectional bus 807, the CPU 801, the ROM 802, the RAM 803, and the backup RAM 804 are connected to each other, and also connected to an input interface 805 and an output interface 806.

Connected to the input interface 805 are various sensors for detecting the operating state (or the state of travel) of the vehicle in which the above vehicle drive apparatus is mounted. Specifically, connected to the input interface 805 are, for example, a lever position sensor 81, an accelerator operation amount sensor 82, an engine revolution speed sensor 83, an output shaft revolution speed sensor 84 that also functions as a vehicle speed sensor, an input shaft revolution speed sensor 85, and a turbine revolution speed sensor 86. The lever position sensor 81, for example, is provided with a plurality of ON-OFF switches that detect that the shift lever 87 has been operated to a shift position such as the parking position “P”, the reverse position “W”, the neutral position “N”, and the drive position “D”.

Signals that indicate, for example, a lever position (operating position) PSH of the shift lever 87, an operation amount θ ACC of an accelerator operation member such as an accelerator pedal (accelerator operation amount), a revolution speed NE of the engine 10 (engine revolution speed), a revolution speed NOUT of the output shaft 48 of the belt-driven continuously variable transmission 40 (output shaft revolution speed), a revolution speed NIN of the input shaft 47 of the belt-driven continuously variable transmission 40 (input shaft revolution speed), and a revolution speed NT of the turbine shaft 28 of the torque converter 20 (turbine revolution speed) are supplied to the electronic control apparatus 80 from each of these various sensors. The turbine revolution speed NT matches the input shaft revolution speed NIN during forward travel, in which state the forward movement clutch C1 of the forward/reverse switching apparatus 30 has been engaged. The output shaft revolution speed NOUT corresponds to a vehicle speed V. The accelerator opening degree θ ACC expresses the driver's requested amount of output.

Linear solenoid valves SLP, SLS, and SLT, an ON-OFF solenoid valve SL1, and the like of the oil pressure control circuit 100 are connected to the output interface 806. The electronic control apparatus 80 controls exciting current of the linear solenoid valves SLP, SLS, and SLT of the oil pressure control circuit 100, and along with respectively regulating control oil pressures PSLP, PSLS, and PSLT that are output from these linear solenoids SLP, SLS, and SLT, switches the ON-OFF solenoid valves SL1 and SL2 of the oil pressure control circuit 100 between an ON state (excited state) and an OFF state (non-excited state). Thus, control to regulate the gearshift oil pressure PIN and the clamping oil pressure POUT of the belt-driven continuously variable transmission 40, control of engagement/release of the friction engaging elements for travel of the forward/reverse switching apparatus 30, control of engagement/release of the lockup clutch 26, and control to regulate the line oil pressure PL, and the like are performed.

FIG. 3 is a circuit diagram that shows an example of an oil pressure control circuit for controlling the power transmission mechanism of the above vehicle drive apparatus.

The oil pressure control circuit 100 shown by way of example in FIG. 3 includes the oil pump 27, the gearshift oil pressure control valve 120, the clamping oil pressure control valve 130, the lockup control valve 140, and the manual valve 170 described above, and further includes a primary regulator valve 110, a switching valve 150, and a garage shift valve 160. The oil pressure control circuit 100 includes the above-described linear solenoid valves SLP, SLS, and SLT, and ON-OFF solenoid valves SL1 and SL2, connected to the electronic control apparatus 80. Note that with respect to the oil pressure control circuit 100 shown in FIG. 3, a part of the oil pressure control circuit of the power transmission mechanism of the vehicle drive apparatus is schematically shown, but other than the configuration shown in FIG. 3, the actual oil pressure control circuit also includes unshown valves, oil paths, and the like.

In the oil pressure control circuit 100, oil pressure generated by the oil pump 27 is regulated to the line oil pressure PL that becomes the source pressure of the oil pressure of various parts by the primary regulator valve 110. The line oil pressure PL regulated by the primary regulator valve 110 is supplied via an oil path 101 to various parts of the oil pressure control circuit 100, such as the gearshift oil pressure control valve 120 and the clamping oil pressure control valve 130.

The primary regulator valve 110 is provided with a first spool 111 a and a second spool 111 b that are movable in the axial direction, and a spring 112 that serves as a biasing means that biases the first spool 111 a and the second spool 111 b in one direction. In FIG. 3, the first spool 111 a provided on the upper side and the second spool 111 b provided on the lower side are both slidable in the vertical direction. The primary regulator valve 110 is provided with control ports 115 a, 115 b, and 115 c, an input port 116, and an output port 117.

With the first spool 111 a, the input port 116 and the output port 117 are put in communication or blocked from each other. The spring 112 is disposed in a compressed state in a control oil pressure chamber 113 c provided on one end side (the lower end side in FIG. 3) of the second spool 111 b. That is, the control oil pressure chamber 113 c is a spring chamber where the spring 112 is disposed. With biasing force of the spring 112, the second spool 111 b and the first spool 111 a are pressed against in the direction (the upper direction in FIG. 3) that the input port 116 and the output port 117 are blocked.

The control port 115 a is connected to a control oil pressure chamber 113 a provided on the other end side (the upper end side in FIG. 3) of the first spool 111 a. Also, the control port 115 a is connected to the oil path 101. Via this control port 115 a, the line oil pressure PL is supplied to a control oil pressure chamber 113 a.

The control port 115 b is connected to a control oil pressure chamber 113 b provided between one end side of the first spool 111 a and the other end side of the second spool 111 b. Also, the control port 115 b is connected to an output port SLSb of the linear solenoid valve SLS via an oil path 102. Via this control port 115 b, the output oil pressure (control oil pressure) PSLS of the linear solenoid valve SLS is supplied to the control oil pressure chamber 113 b.

The control port 115 c is connected to the above-described control oil pressure chamber 113 c. Also, the control port 115 c is connected to an output port 157 a of a switching valve 150 described below via an oil path 103. When the switching valve 150 is held in the ON position, via this control port 115 c, the output oil pressure (control oil pressure) PSLT of the linear solenoid valve SLT is supplied to the control oil pressure chamber 113 c. On the other hand, when the switching valve 150 is held in the OFF position, the control oil pressure PSLT is not supplied to the control oil pressure chamber 113 c.

The input port 116 is connected to the oil path 101. The line oil pressure PL is input via the input port 116. The output port 117 is connected to an unshown secondary regulator valve.

The first spool 111 a slides vertically according to the balance of the combined force of the line oil pressure PL that is introduced to the control oil pressure chamber 113 a, the control oil pressure PSLS that is introduced to the control oil pressure chamber 113 b, or the control oil pressure PSLT that is introduced to the control oil pressure chamber 113 c, and the biasing force of the spring 112. While the combined force is greater than the force from the line oil pressure PL, the input port 116 and the output port 117 are blocked from each other. On the other hand, when the line oil pressure PL is greater than the combined force, the first spool 111 a moves downward in FIG. 3, so the input port 116 and the output port 117 are put in communication with each other. Thus, by oil pressure from the oil path 101 being drained via the output port 117, the line oil pressure PL is adjusted. Accordingly, by controlling the oil pressure of at least one of the control oil pressure PSLS of the linear solenoid valve SLS and the control oil pressure PSLT of the linear solenoid valve SLT, it is possible to control regulation of the line oil pressure PL.

Here, the first spool 111 a and the second spool 111 b are formed with the same diameter. Therefore, the acting area (pressure receiving area) of the control oil pressure PSLS supplied via the control port 115 b on the first spool 111 a, the acting area (pressure receiving area) of the control oil pressure PSLS on the second spool 111 b, and the acting area (pressure receiving area) of the control oil pressure PSLT supplied via the control port 115 c on the second spool 111 b are the same.

Thus, the higher oil pressure among the control oil pressure PSLS introduced to the control oil pressure chamber 113 b and the control oil pressure PSLT introduced to the control oil pressure chamber 113 c contributes to the combined force described above. That is, the primary regulator valve 110 is configured to control regulation of the line oil pressure PL by selecting the higher oil pressure among the control oil pressure PSLS and the control oil pressure PSLT. Specifically, the primary regulator valve 110 is configured such that when the control oil pressure PSLS is higher than the control oil pressure PSLT, the first spool 111 a moves vertically in a state separated from the second spook 111 b, and when the control oil pressure PSLT is higher than the control oil pressure PSLS, both spools 111 a and 111 b move vertically together in contact with each other. In this way, when controlling the line oil pressure PL, without computing, for example, the two control oil pressures PSLS and PSLT, the higher oil pressure among the two control oil pressures PSLS and PSLT is selected automatically, so it is possible to easily control the line oil pressure PL.

Note that a configuration may also be adopted in which a primary regulator valve 210 as shown in FIG. 5 is used instead of the primary regulator valve 110 as described above. In FIG. 5, only a part of an oil pressure control circuit 100′ is shown, but other than the primary regulator valve 210, the configuration is the same as the oil pressure control circuit 100 shown in FIG. 3. As shown in FIG. 5, the primary regulator valve 210 has about the same configuration as the primary regulator valve 110 described above, but the location where a spring 212 is disposed is different from the location in the primary regulator valve 110. The spring 212 is disposed in a control oil pressure chamber 213 b to which a control port 215 b is connected, and is provided in a compressed state between one end side of a first spool 211 a and a valve body.

A configuration may also be adopted in which when the maximum value of the control oil pressure PSLT of the linear solenoid valve SLT that is introduced to the control oil pressure chamber 113 c is less than the maximum value of the control oil pressure PSLS of the linear solenoid valve SLS that is introduced to the control oil pressure chamber 113 b, and thus it is difficult to secure the necessary line oil pressure PL with the above control oil pressure PSLT, the second spool 111 b is formed with a larger diameter than the first spool 111 a, such that the acting area of the control oil pressure PSLT on the second spool 111 b is larger than the acting area of the control oil pressure PSLS on the first spool 111 a. By adopting such a configuration, according to the ratio of those acting areas, the force of the control oil pressure PSLT that acts on the second spool 111 b is amplified, so even when the control oil pressure PSLT is low, it is possible to secure the necessary line oil pressure PL.

The gearshift oil pressure control valve 120 is provided with a spool 121 that is movable in the axial direction and a spring 122 that serves as a biasing means that biases the spool 121 in one direction. The gearshift oil pressure control valve 120 is configured to continuously control regulation of the line oil pressure PL that becomes the source pressure, using the output oil pressure (control oil pressure) PSLP of the linear solenoid valve SLP as a pilot pressure. The oil pressure (gearshift oil pressure PIN) adjusted by the gearshift oil pressure control valve 120 is supplied to the oil pressure actuator 413 of the driving-side pulley 41 via an oil path 109 a.

Accordingly, control of regulation of the gearshift oil pressure PIN is performed by controlling the control oil pressure PSLP of the linear solenoid valve SLP. Because the above control oil pressure PSLP changes linearly according to the exciting current, a gear ratio γ of the belt-driven continuously variable transmission 40 changes continuously according to this control oil pressure PSLP. In this case, for example, such that a target input shaft revolution speed is set based on the vehicle state indicated by the actual vehicle speed V and the accelerator opening degree θ ACC from a gearshift map that has been stored in advance in the ROM 802 matches the actual input shaft revolution speed NIN, the gear ratio γ of the belt-driven continuously variable transmission 40 is changed according to the difference (deviation) between those revolution speeds. The gearshift map indicates gearshift conditions, and for example, provides the relationship between the vehicle speed V and the target input shaft revolution speed, which is the target input revolution speed of the belt-driven continuously variable transmission 40, using the accelerator opening degree θ ACC as a parameter.

The clamping oil pressure control valve 130 is provided with a spool 131 that is movable in the axial direction and a spring 132 that serves as a biasing means that biases the spool 131 in one direction. The clamping oil pressure control valve 130 is configured to continuously control regulation of the line oil pressure PL that becomes the source pressure, using the control oil pressure PSLS of the linear solenoid valve SLS as a pilot pressure. The oil pressure (clamping oil pressure POUT) adjusted by the clamping oil pressure control valve 130 is supplied to the oil pressure actuator 423 of the driven-side pulley 42 via the oil path 109 b.

Accordingly, control of regulation of the clamping oil pressure POUT is performed by controlling the control oil pressure PSLS of the linear solenoid valve SLS. Because the above control oil pressure PSLS changes linearly according to the exciting current, the belt clamping pressure of the belt-driven continuously variable transmission 40 is changed continuously according to this control oil pressure PSLS. In this case, for example, the clamping oil pressure POUT of the oil pressure actuator 423 of the driven-side pulley 42 is regulated such that a necessary target gearshift oil pressure, that is set based on the vehicle state indicated by the actual gear ratio γ and the accelerator opening degree θ ACC from a clamping map that has been stored in advance in the ROM 802, is obtained, and the belt clamping pressure of the belt-driven continuously variable transmission 40 is changed according to this clamping pressure POUT. The clamping map provides the relationship between the gear ratio γ and the necessary target gearshift oil pressure, using the accelerator opening degree θ ACC as a parameter, and this relationship is obtained through testing in advance such that belt slippage does not occur.

Here, the gearshift oil pressure PIN and the clamping oil pressure POUT are obtained by regulating the line oil pressure PL that becomes the source pressure, so it is necessary that the line oil pressure PL is at least no less than the gearshift oil pressure PIN and the clamping oil pressure POUT. Therefore, it is necessary to drive the oil pump 27 such that a line oil pressure PL is obtained that is no less than the target gearshift oil pressure and the target clamping oil pressure necessary in order to control the gear ratio γ and the clamping pressure of the belt-driven continuously variable transmission 40. In this case, the necessary target gearshift oil pressure and target clamping oil pressure are set as shown in FIG. 4, for example. FIG. 4 shows an example of changes in the set values of the necessary target gearshift oil pressure and target clamping oil pressure according to the gear ratio γ of the belt-driven continuously variable transmission 40, under conditions in which the input shaft revolution speed NIN and the input torque are fixed. In FIG. 4, the broken line indicates changes in the target gearshift oil pressure, and the single-dotted chained line indicates changes in the target clamping oil pressure.

On an acceleration side (the left side in FIG. 4) where the gear ratio γ is lower than γ1, the target gearshift oil pressure is set higher than the target clamping oil pressure, and the difference between those oil pressures increases as the degree of acceleration increases. On the other hand, on a deceleration side (the right side in FIG. 4) where the gear ratio γ is higher than γ1, the target clamping oil pressure is set higher than the target gearshift oil pressure, and the difference between those oil pressures increases as the degree of deceleration increases. That is, the set values of the target gearshift oil pressure and the target clamping oil pressure are reversed with the change in the gear ratio γ (with the above gear ratio γ1 as the switching point). In order to suppress driving failure of the oil pump 27, when the gear ratio γ is higher than γ1, it is preferable to set the line oil pressure PL to be the same or slightly higher than the target clamping oil pressure, and when the gear ratio γ is lower than γ1, it is preferable to set the line oil pressure PL to be the same or slightly higher than the target gearshift oil pressure. A gear ratio of “1” is given as the specific value of the gear ratio γ1, but this is not a limitation.

The switching valve 150 switches the supply destination (output destination) of the control oil pressure PSLT of the linear solenoid valve SLT to either one of the primary regulator valve 110 and the lockup control valve 140, described below, and switches the oil pressure supplied to the lockup control valve 140 to either one of the control oil pressure PSLT of the linear solenoid valve SLT and the output oil pressure (control oil pressure) of the ON-OFF solenoid valve SL2. The switching valve 150 is configured to be capable of switching between the ON position shown in the right half in FIG. 3 and the OFF position shown in the left half in FIG. 3 by controlling the control oil pressure of the ON-OFF solenoid valve SL2.

The switching valve 150 is provided between the primary regulator valve 110 and the linear solenoid valve SLT. The switching valve 150 is provided with a spool 151 that is movable in the axial direction and a spring 152 that serves as a biasing means that biases the spool 151 in one direction. In FIG. 3, the spool 151 is slidable in the vertical direction. The spring 152 is disposed in a compressed state in a spring chamber 154 provided on one end side of the spool 151 (the upper end side in FIG. 3). With biasing force of the spring 152, the spool 151 is pressed against in the direction (the lower direction in FIG. 3) that the switching valve 150 is held in the above-described OFF position. The switching valve 150 is provided with a control port 155, an input port 156, and output ports 157 a and 157 b.

The control port 155 is connected to a control oil pressure chamber 153 provided on the other end side (the lower end side in FIG. 3) of the spool 151. Also, the control port 155 is connected to an output port SL2 b of the ON-OFF solenoid valve SL2. Control oil pressure of the ON-OFF solenoid valve SL2 is supplied to the control oil pressure chamber 153 via the control port 155.

The input port 156 is connected to an output port SLTb of the linear solenoid valve SLT. The control oil pressure PSLT of the linear solenoid valve SLT is input via the input port 156. The output port 157 a is connected to the control port 115 c of the primary regulator valve 110 via the oil path 103. Also, the output port 157 b is connected to a control port 145 a of the lockup control valve 140 via an oil path 104.

Next is a description of switching operation of the switching valve 150.

In this embodiment, the ON-OFF solenoid valve SL2 is provided as a control valve for performing switching of the switching valve 150. The ON-OFF solenoid valve SL2 is configured to switch between the ON state and the OFF state according to commands sent from the electronic control apparatus 80. It is possible to use a normally closed-type electromagnetic valve as described below as the ON-OFF solenoid valve SL2, and a configuration may also be adopted in which a normally open-type electromagnetic valve is used. Also note that instead of the ON-OFF solenoid valve SL2, it is possible to use a linear-type electromagnetic valve, a duty-type electromagnetic valve, a three-way valve-type electromagnetic valve, or the like as the control valve for performing switching of the switching valve 150.

Specifically, when the ON-OFF solenoid valve SL2 is in the ON state, a predetermined control oil pressure is output from the output port SL2 b, and that control oil pressure is supplied to the switching valve 150. With that control oil pressure, the spool 151 moves upward against the biasing force of the spring 152. Thus, the switching valve 150 is held in the ON position. On the other hand, when the ON-OFF solenoid valve SL2 is in the OFF state, output of that control oil pressure is stopped. Then, the spool 151 moves downward due to the biasing force of the spring 152 and returns to its original position. Thus, the switching valve 150 is held in the OFF position. Also, a second modulator oil pressure PM2 regulated by a second modulator valve using the line oil pressure PL as the source pressure is introduced to the ON-OFF solenoid valve SL2 via an input port SL2 a.

The ON-OFF solenoid valve SL2 is controlled to the OFF state when performing engagement/release of the lockup clutch 26 (during an engagement/release operation of the lockup clutch 26). In this case, supply of the control oil pressure of the ON-OFF solenoid valve SL2 to the control oil pressure chamber 153 is stopped, so the switching valve 150 is held in the OFF position. Thus, the input port 156 and the output port 157 b are in communication. Due to the input port 156 and the output port 157 b being in communication, the control oil pressure PSLT of the linear solenoid valve SLT is supplied to a control oil pressure chamber 143 of the lockup control valve 140.

On the other hand, the ON-OFF solenoid valve SL2 is controlled to the ON state when not performing engagement/release of the lockup clutch 26 (when the lockup clutch 26 is in a state of complete engagement or complete release). Along with this, control oil pressure of the ON-OFF solenoid valve SL2 is introduced to the control oil pressure chamber 153 via the control port 155, and thus the switching valve 150 is held in the ON position. Thus, the input port 156 and the output port 157 a are in communication, and the control port 155 and the output port 157 b are in communication. Due to the input port 156 and the output port 157 a being in communication, the control oil pressure PSLT of the linear solenoid valve SLT is supplied to the control oil pressure chamber 113 c of the primary regulator valve 110. Also, due to the control port 155 and the output port 157 b being in communication, the control oil pressure of the ON-OFF solenoid valve SL2 is supplied to the control oil pressure chamber 143 of the lockup control valve 140.

Accordingly, when the switching valve 150 is held in the ON position, the control oil pressure PSLT is introduced to the control oil pressure chamber 113 c of the primary regulator valve 110, so in the primary regulator valve 110, the higher oil pressure among the above-described control oil pressure PSLS and the above-described control oil pressure PSLT is selected. Therefore, regulation of the line oil pressure PL is controlled based on that higher oil pressure. On the other hand, when the switching valve 150 is held in the OFF position, the control oil pressure PSLT is not introduced to the control oil pressure chamber 113 c, so in the primary regulator valve 110, the control oil pressure PSLS is inevitably selected. Therefore, regulation of the line oil pressure PL is controlled based on the control oil pressure PSLS.

Also, when the switching valve 150 is being held in the OFF position, the above-described control oil pressure PSLT is introduced to the control oil pressure chamber 143, and engagement/release of the lockup clutch 26 is controlled based on this control oil pressure PSLT. On the other hand, when the switching valve 150 is being held in the ON position, the control oil pressure of the ON-OFF solenoid valve SL2 is introduced to the control oil pressure chamber 143 of the lockup control valve 140, and in this case, the lockup clutch 26 is held in a completely engaged state. The control oil pressure of the ON-OFF solenoid valve SL2 is set to a pressure that is no less than the maximum value of the above control oil pressure PSLT, and that is a pressure at which it is possible to hold the lockup clutch 26 in the completely engaged state. Control of engagement/release of the lockup clutch 26 will be described below.

The manual valve 170 is a switching valve that switches the supply of oil pressure to the forward movement clutch C1 and the rearward movement brake B1 of the forward/rearward switching apparatus 30 according to operation of the shift lever 87. The manual valve 170 is switched corresponding to the shift positions of the shift lever 87, such as the parking position “P”, the reverse position “R”, the neutral position “N”, and the drive position “D”.

When the manual valve 170 is being switched corresponding to the parking position “P” and the neutral position “N” of the shift lever 87, oil pressure is not supplied to an oil pressure servo of the forward movement clutch C1 and an oil pressure servo of the rearward movement brake B1. Working oil of the oil pressure servo of the forward movement clutch C1 and the oil pressure servo of the rearward movement brake B1 is drained via the manual valve 170. Thus, both the forward movement clutch C1 and the rearward movement brake B1 are released.

When the manual valve 170 is being switched corresponding to the reverse position “R” of the shift lever 87, oil pressure is supplied to the oil pressure servo of the rearward movement brake B1, and oil pressure is not supplied to the oil pressure servo of the forward movement clutch C1. Working oil of the oil pressure servo of the forward movement clutch C1 is drained via the manual valve 170. Thus, the rearward movement brake B1 is engaged, and the forward movement clutch C1 is released.

When the manual valve 170 is being switched corresponding to the drive position “D” of the shift lever 87, an input port 176 and an output port 177 are in communication, and so oil pressure is supplied to the oil pressure servo of the forward movement clutch C1. On the other hand, oil pressure is not supplied to the oil pressure servo of the rearward movement brake B1. Working oil of the oil pressure servo of the rearward movement brake B1 is drained via the manual valve 170. Thus, the forward movement clutch C1 is engaged, and the rearward movement brake B1 is released. The supply of oil pressure that accompanies engagement of the forward movement clutch C1 is performed via the garage shift valve 160, described next.

The garage shift valve 160 is a switching valve that, during garage shifting, switches the oil path corresponding to a state of engagement transition or a state of engagement (a state of complete engagement) of the friction engaging elements for travel (the forward movement clutch C1 and the rearward movement brake B1) of the forward/reverse switching apparatus 30. Due to this switching of the garage shift valve 160, for example, when the shift lever 87 has been operated from a non-travel position such as the parking position “P” or the neutral position “N” to a travel position such as the drive position “D” when starting to move the vehicle or the like, the oil pressure supplied to the oil pressure servo of the forward movement clutch C1 is switched between an engagement transition oil pressure that corresponds to the state of engagement transition and an engagement holding oil pressure that corresponds to the state of complete engagement. Likewise, when the shift lever 87 has been operated to the reverse position “R”, due to switching of the garage shift valve 160, the oil pressure supplied to the oil pressure servo of the rearward movement brake B1 is switched between the engagement transition oil pressure that corresponds to the state of engagement transition and the engagement holding oil pressure that corresponds to the state of complete engagement. Note that below, as a representative example, a case will be described in which the oil pressure supplied to the oil pressure servo of the forward movement clutch C1 is switched by the garage shift valve 160.

Specifically, the garage shift valve 160 is configured such that when the forward movement clutch C1 is in the state of engagement transition, the garage shift valve 160 is switched to the control position shown in the left half in FIG. 3, and when the forward movement clutch C1 is in the state of complete engagement, the garage shift valve 160 is switched to the normal position shown in the right half in FIG. 3. Switching of the garage shift valve 160 is performed by controlling the output oil pressure (control oil pressure) of the ON-OFF solenoid valve SL1.

The garage shift valve 160 is provided with a spool 161 that is movable in the axial direction and a spring 162 that serves as a biasing means that biases the spool 161 in one direction. The spool 161 is provided so as to be slidable vertically in FIG. 3. The spring 162 is disposed in a compressed state in a spring chamber 164 provided on one end side (the lower end side in FIG. 3) of the spool 161. Due to the biasing force of the spring 162, the spool 161 is pressed against in the direction (upward in FIG. 3) that holds the garage shift valve 160 in the aforementioned normal direction. The garage shift valve 160 is provided with a control port 165, input ports 166 a and 166 b, an output port 167, and a drain port 169.

The control port 165 c is connected to a control oil pressure chamber 163 that is provided on the other end side (the upper end side in FIG. 3) of the spool 161. Also, the control port 165 is connected to an output port SL1 b of the ON-OFF solenoid valve SL1. Control oil pressure of the ON-OFF solenoid valve SL1 is supplied to the control oil pressure chamber 163 via the control port 165.

The input port 166 a is connected to an unshown second modulator valve. The aforementioned second modulator oil pressure PM2 that has been regulated by the second modulator valve is input via the input port 166 a. The input port 166 b is connected to an output port SLTc of the linear solenoid valve SLT via an oil path 105. The control oil pressure PSLT of the linear solenoid valve SLT is input via the input port 166 b.

The output port 167 is connected to the input port 176 of the manual valve 170 via an oil path 107. The drain port 169 is connected to the spring chamber 164.

Next is a description of switching operation of the garage shift valve 160.

In this embodiment, the ON-OFF solenoid valve SL1 is provided as a control valve for performing switching of the garage shift valve 160. The ON-OFF solenoid valve SL1 is configured to switch between the ON state and the OFF state according to commands sent from the electronic control apparatus 80. It is possible to use a normally closed-type electromagnetic valve as described below as the ON-OFF solenoid valve SL1, and a configuration may also be adopted in which a normally open-type electromagnetic valve is used. Also note that instead of the ON-OFF solenoid valve SL1, it is possible to use a linear-type electromagnetic valve, a duty-type electromagnetic valve, a three-way valve-type electromagnetic valve, or the like as the control valve for performing switching of the garage shift valve 160.

Specifically, when the ON-OFF solenoid valve SL1 is in the ON state, in which electric power is turned on, a predetermined control oil pressure is output from the output port SL1 b, and that control oil pressure is supplied to the garage shift valve 160. With that control oil pressure, the spool 161 moves downward against the biasing force of the spring 162. Thus, the garage shift valve 160 is held in the control position. On the other hand, when the ON-OFF solenoid valve SL1 is in the OFF state, in which electric power is not turned on, output of that control oil pressure is stopped. With that biasing force of the spring 162, the spool 161 moves upward. Thus, the garage shift valve 160 is held in the normal position. Also, a first modulator oil pressure PM1 regulated by a first modulator valve using the line oil pressure PL as the source pressure is introduced to the ON-OFF solenoid valve SL1 via an input port SL1 a. Here, the aforementioned second modulator valve is provided on the downstream side of the primary regulator valve 110, and the first modulator valve is provided on the downstream side of the second modulator valve. Thus, the first modulator oil pressure PM1 is set lower than the second modulator oil pressure PM2.

The ON-OFF solenoid valve SL1 is controlled to the ON state during a state of engagement transition of the forward movement clutch C1 of the forward/reverse switching apparatus 30, i.e., from when the engagement operation of the forward movement clutch C1 begins until the forward movement clutch C1 reaches the state of complete engagement. Along with this, control oil pressure of the ON-OFF solenoid valve SL1 is introduced to the control oil pressure chamber 163 via the control port 165, and thus the garage shift valve 160 is held in the control position. Thus, the input port 166 b and the output port 167 are in communication.

In this case, the input port 176 and the output port 177 of the manual valve 170 are in communication, so due to the input port 166 b and the output port 167 being in communication, the control oil pressure PSLT of the linear solenoid valve SLT is supplied to the oil pressure servo of the forward movement clutch C1. Accordingly, when the forward movement clutch C1 is in the state of engagement transition, the engagement transition oil pressure supplied to the oil pressure servo is the control oil pressure PSLT. Thus, engagement transition of the forward movement clutch C1 is controlled by the linear solenoid valve SLT. Here, because the control oil pressure PSLT of the linear solenoid valve SLT serving as the engagement transition oil pressure changes linearly according to the exciting current, during garage shifting, smooth engagement of the forward movement clutch C1 is possible, so it is possible to suppress a shock that accompanies engagement of the forward movement clutch C1.

On the other hand, the ON-OFF solenoid valve SL1 is controlled to the OFF state during a state of complete engagement in which the forward movement clutch C1 is completely engaged (for example, during regular travel or the like). In this case, supply of the control oil pressure of the ON-OFF solenoid valve SL1 to the control oil pressure chamber 163 is stopped, so the garage shift valve 160 is held in the normal position. Thus, the input port 166 a and the output port 167 are in communication. In this case, the input port 176 and the output port 177 of the manual valve 170 are in communication, so due to the input port 166 a and the output port 167 being in communication, the second modulator oil pressure PM2 is supplied to the oil pressure servo of the forward movement clutch C1. Accordingly, when the forward movement clutch C1 is in the state of complete engagement, the engagement holding oil pressure supplied to the oil pressure servo is the second modulator oil pressure PM2. Here, the second modulator oil pressure PM2 is set to a fixed pressure (clutch pressure) that is no less than the control oil pressure PSLT, so it is possible to reliably hold the forward movement clutch C1 in the state of complete engagement.

Note that in a case other than that described above (a case other than when in the state of engagement transition or the state of complete engagement), the ON-OFF solenoid valve SL1 is controlled to the OFF state, and the garage shift valve 160 is held in the normal position. However, if the manual valve 170 is being switched corresponding to a position of the shift lever 87 other than a travel position such as the drive position “D”, the input port 176 and the output port 177 of the manual valve 170 are blocked from each other, so the second modulator oil pressure PM2 is not supplied to the oil pressure servo of the forward movement clutch C1.

The lockup control valve 140 controls engagement/release of the lockup clutch 26. Specifically, lockup control valve 140 is configured to control engagement/release of the lockup clutch 26 by controlling the lockup differential pressure ΔP (ΔP=lockup engaging oil pressure PON−lockup releasing oil pressure POFF). Control of the lockup differential pressure ΔP by the lockup control valve 140 is performed by controlling the control oil pressure PSLT of the linear solenoid valve SLT.

The lockup control valve 140 is provided with a spool 141 that is movable in the axial direction and a spring 142 that serves as a biasing means that biases the spool 141 in one direction. In FIG. 3, the spool 141 is slidable in the vertical direction. The spring 142 is disposed in a compressed state in a spring chamber 144 provided on one end side of the spool 141 (the lower end side in FIG. 3). With biasing force of the spring 142, the spool 141 is pressed against in the direction (the upper direction in FIG. 3) that the lockup control valve 140 is held in the OFF position shown in the left half in FIG. 3. The lockup control valve 140 is provided with a control port 145 a, a backup port 145 b, input ports 146 a and 146 b, a releasing-side port 147 a, an engaging-side port 147 b, a feedback port 148, and drain ports 149 a and 149 b.

The control port 145 a is connected to a control oil pressure chamber 143 provided on the other end side (the upper end side in FIG. 3) of the spool 141. Also, the control port 145 a is connected to the output port 157 b of the switching valve 150 via the oil path 104. When the switching valve 150 is being held in the OFF position, the control oil pressure PSLT of the linear solenoid valve SLT is supplied to the control oil pressure chamber 143, and when the switching valve 150 is being held in the ON position, the control oil pressure of the ON-OFF solenoid valve SL2 is supplied to the control oil pressure chamber 143.

The backup port 145 b is connected to the spring chamber 144. Also, the backup port 145 b is connected to the output port SL1 b of the ON-OFF solenoid valve SL1 via an oil path 108. The control oil pressure of the ON-OFF solenoid valve SL1 is supplied to the spring chamber 144 via the backup port 145 b.

The input ports 146 a and 146 b are each connected to an unshown secondary regulator valve, which is connected to the output port 117 of the primary regulator valve 110. A secondary oil pressure PSEC that has been regulated by the secondary regulator valve is input via the input ports 146 a and 146 b.

The release-side port 147 a is connected to the releasing-side oil pressure chamber 262 of the lockup clutch 26 via an oil path 106 a. The engaging-side port 147 b is connected to an engaging-side oil pressure chamber 261 of the lockup clutch 26 via an oil path 106 b.

The feedback port 148 is connected to the spring chamber 144. Also, the feedback port 148 is connected to the oil path 106 b. The same oil pressure as the lockup engaging oil pressure PON is supplied to the spring chamber 144 via the feedback port 148.

Next is a description of operation of the lockup clutch 26 by the lockup control valve 140.

First, when the ON-OFF solenoid valve SL2 is in the OFF state, and the switching valve 150 is being held in the OFF position, the control oil pressure PSLT of the linear solenoid valve SLT is introduced to the control oil pressure chamber 143. At this time, the lockup control valve 140 enters a state (the ON state) in which according to that control oil pressure PSLT, the spool 141 has moved downward against the biasing force of the spring 142. In this case, the spool 141 moves further downward as the control oil pressure PSLT increases. In the right half in FIG. 3, a state is shown in which the spool 141 has moved downward as far as possible. In this state shown in the right half in FIG. 3, the input port 146 b and the engaging-side port 147 b are in communication, and the releasing-side port 147 a and the drain port 149 a are in communication. At this time, the lockup clutch 26 is in a completely engaged state.

When the lockup control valve 140 is in the ON state, the spool 141 slides vertically according to the balance of the combined force of the control oil pressure PSLT that is introduced to the control oil pressure chamber 143 and the lockup releasing oil pressure POFF that acts on the releasing-side port 147 a, and the combined force of the lockup engaging oil pressure PON that is introduced to the spring chamber 144 and the biasing force of the spring 142. Here, the lockup clutch 26 is engaged according to the lockup differential pressure ΔP. Control of the lockup differential pressure ΔP is performed by controlling the control oil pressure PSLT of the linear solenoid valve SLT. Because the above control oil pressure PSLT changes linearly according to the exciting current, it is possible to continuously adjust the lockup differential pressure ΔP. Along with this, it is possible to continuously change the degree of engagement (clutch capacity) of the lockup clutch 26 according to the lockup differential pressure ΔP.

More specifically, as the control oil pressure PSLT increases, the lockup differential pressure ΔP increases, and thus the degree of engagement of the lockup clutch 26 increases. In this case, the working oil from the aforementioned secondary regulator valve is supplied to the engaging-side oil pressure chamber 261 of the lockup clutch 26 via the input port 146 b, the engaging-side port 147 b, and the oil path 106 b. On the other hand, the working oil of the releasing-side oil pressure chamber 262 is discharged via the oil path 106 a, the releasing-side port 147 a, and the drain port 149 a. When the lockup differential pressure ΔP becomes at least a predetermined value, the lockup clutch 26 reaches complete engagement.

Conversely, as the control oil pressure PSLT decreases, the lockup differential pressure ΔP decreases, and thus the degree of engagement of the lockup clutch 26 decreases. In this case, the working oil from the aforementioned secondary regulator valve is supplied to the releasing-side oil pressure chamber 262 via the input port 146 a, the releasing-side port 147 a, and the oil path 106 a. On the other hand, the working oil of the engaging-side oil pressure chamber 261 is discharged via the oil path 106 b, the engaging-side port 147 b, and the drain port 149 b. When the lockup differential pressure ΔP becomes a negative value, the lockup clutch 26 is in a released state.

On the other hand, when supply of the control oil pressure PSLT of the linear solenoid valve SLT to the control oil pressure chamber 143 is stopped, the lockup control valve 140, enters a state (OFF state) in which, as shown in the left half in FIG. 3, the spool 141 moves upward due to the biasing force of the spring 142, and is held at its original position. In this OFF state, the input port 146 a and the releasing-side port 147 a are in communication, and the engaging-side port 147 b and the drain port 149 b are in communication. At this time, the lockup clutch 26 is in a released state.

Next, when the ON-OFF solenoid valve SL2 is in the OFF state, and the switching valve 150 is being held in the ON position, the control oil pressure of the ON-OFF solenoid valve SL2 is introduced to the control oil pressure chamber 143. Because the control oil pressure of the ON-OFF solenoid valve SL2 is set to a fixed pressure that is no less than the above control oil pressure PSLT, in the ON state of the ON-OFF solenoid valve SL2, the lockup control valve 140 is held in a state in which the spool 141 shown in the right half in FIG. 3 has moved downward as much as possible. Accordingly, the lockup clutch 26 is held in a completely engaged state.

When the ON-OFF solenoid valve SL1 is in the ON state, a control is performed to forcibly release the lockup clutch 26, without controlling engagement/release of the lockup clutch 26 as described above. In other words, when the garage shift valve 160 is held at the control position, and control of engagement transition of the forward movement clutch C1 is performed, the lockup clutch 26 is forcibly released.

As described above, when the ON-OFF solenoid valve SL1 is in the ON state, the control oil pressure of the ON-OFF solenoid valve SL1 is introduced to the spring chamber 144. Due to the control oil pressure of the ON-OFF solenoid valve SL1, force in the same direction as the biasing force of the spring 142 is applied to the spool 141, so regardless of whether or not the control oil pressure PSLT of the linear solenoid valve SLT or the control oil pressure of the ON-OFF solenoid valve SL1 is supplied to the control oil pressure chamber 143, the lockup control valve 140 is held in the OFF state shown in the left half in FIG. 3. This is accompanied by the lockup clutch 26 being forcible released.

By forcing the lockup clutch 26 OFF in this manner, for example, when performing garage shifting when beginning vehicle movement or the like, even if a failure of the linear solenoid valve SLT to turn ON or the like occurs, it is possible to reliably return the lockup clutch 26 to the released state, and so it is possible to prevent the occurrence of an engine stall. In order to reliably return the lockup clutch 26 to the released state, a configuration may be adopted in which the combined force of the force due to the control oil pressure of the ON-OFF solenoid valve SL1 and the biasing force of the spring 142 is larger than the force due to the control oil pressure of the ON-OFF solenoid valve SL2. In this case, if the control oil pressure of the ON-OFF solenoid valve SL1 is smaller than the control oil pressure of the ON-OFF solenoid valve SL2, for example, by setting the acting area (pressure receiving area) of the control oil pressure of the ON-OFF solenoid valve SL1 on the spool 141 to be larger than the acting area (pressure receiving area) of the control oil pressure of the ON-OFF solenoid valve SL2 on the spool 141, it is possible to reliably return the lockup clutch 26 to the released state.

The linear solenoid valves SLT, SLP, and SLS, are, for example, normally open-type electromagnetic valves. That is, when electrical power is not turned on, the input port and the output port are in communication, and oil pressure that has been input is output from the output port as a control oil pressure. On the other hand, when electrical power is turned on, regulation of oil pressure that has been input from the input port is controlled according to the exciting current determined by a duty signal sent from the electronic control apparatus 80, and this oil pressure is output from the output port as a control oil pressure. In this case, regulation is controlled such that the control oil pressure decreases as the exciting current increases. When the exciting current is at least a predetermined value, the control oil pressure is “0”, and output of the control oil pressure is stopped. For example, the control oil pressure PSLT of the linear solenoid valve SLT changes linearly according to the exciting current. Likewise, the control oil pressures PSLP and PSLS of the linear solenoid valves SLP and SLS also change linearly according to the exciting current. Note that a configuration may be adopted in which a normally closed-type electromagnetic valve is used as the linear solenoid valves SLT, SLP, and SLS.

The linear solenoid valve SLT is provided in order to perform control of regulation of the line oil pressure PL, control of engagement/release of the lockup clutch 26, and control of engagement transition of the forward movement clutch C1 (control of engagement transition oil pressure). A configuration may also be adopted in which instead of the linear solenoid valve SLT, a duty-type electromagnetic valve is used as an electromagnetic valve for performing these controls.

In more detail, the second modulator oil pressure PM2 that has been regulated by the second modulator valve is introduced to the linear solenoid valve SLT via an input port SLTa. Thus, when electrical power is not turned on, the second modulator oil pressure PM2 is output as the control oil pressure PSLT, and when electrical power is turned on, oil pressure obtained by linearly controlling regulation of the second modulator oil pressure PM2 according to the exciting current is output as the control oil pressure PSLT.

The control oil pressure PSLT to be output from the output port SLTb is first supplied to the switching valve 150. The switching valve 150 switches between supplying the control oil pressure PSLT to the primary regulator valve 110 via the oil path 103, and supplying the control oil pressure PSLT to the lockup control valve 140 via the oil path 104. That is, the switching valve 150 switches between control of regulation of the line oil pressure PL, and control of engagement/release of the lockup clutch 26. Control of regulation of the line oil pressure PL, and control of engagement/release of the lockup clutch 26 are performed based on the control oil pressure PSLT. Also, the control oil pressure PSLT to be output from the output port SLTb is supplied to the garage shift valve 160 via the oil path 105. Control of engagement transition of the forward movement clutch C1 is performed based on that control oil pressure PSLT.

The linear solenoid valve SLP is provided in order to control regulation of the gearshift oil pressure PIN of the belt-driven continuously variable transmission 40. A configuration may also be adopted in which instead of the linear solenoid valve SLP, a duty-type electromagnetic valve is used as an electromagnetic valve for controlling regulation of the gearshift oil pressure PIN.

In more detail, the second modulator oil pressure PM2 that has been regulated by the second modulator valve is introduced to the linear solenoid valve SLP via an input port SLPa. Thus, when electrical power is not turned on, the second modulator oil pressure PM2 is output as the control oil pressure PSLP, and when electrical power is turned on, oil pressure obtained by linearly controlling regulation of the second modulator oil pressure PM2 according to the exciting current is output as the control oil pressure PSLP. The control oil pressure PSLP to be output from an output port SLPb is supplied to the gearshift oil pressure control valve 120. Control of regulation of the gearshift oil pressure PIN of the belt-driven continuously variable transmission 40 is performed based on this control oil pressure PSLP.

The linear solenoid valve SLS is provided in order to control regulation of the line oil pressure PL, and to control regulation of the clamping oil pressure POUT of the belt-driven continuously variable transmission 40. A configuration may also be adopted in which instead of the linear solenoid valve SLS, a duty-type electromagnetic valve is used as a control valve for performing these controls.

In more detail, the second modulator oil pressure PM2 that has been regulated by the second modulator valve is introduced to the linear solenoid valve SLS via an input port SLSa. Thus, when electrical power is not turned on, the second modulator oil pressure PM2 is output as the control oil pressure PSLS, and when electrical power is turned on, oil pressure obtained by linearly controlling regulation of the second modulator oil pressure PM2 according to the exciting current is output as the control oil pressure PSLS. The control oil pressure PSLS to be output from an output port SLSb is supplied to the primary regulator valve 110 and the clamping oil pressure control valve 130 via the oil path 102. Control of regulation of the line oil pressure PL and control of regulation of the clamping oil pressure POUT of the belt-driven continuously variable transmission 40 are performed based on this control oil pressure PSLS.

As described above, in the oil pressure control circuit 100 with the above configuration, control of regulation of the line oil pressure PL, control of engagement/release of the lockup clutch 26, and control of engagement transition of the forward movement clutch C1 are performed with a single electromagnetic valve (the linear solenoid valve SLT). Also, control of regulation of the line oil pressure PL and control of the clamping oil pressure POUT are performed with another electromagnetic valve (the linear solenoid valve SLS). Accordingly, it is possible to reduce the number electromagnetic valves in comparison to a case in which the respective controls are performed by dedicated electromagnetic valves. Thus, it is possible to avoid increases in apparatus cost and size.

Also, because regulation of the line oil pressure PL is controlled with the control oil pressure PSLS of the linear solenoid valve SLS and the control oil pressure PSLT of the linear solenoid valve SLT, it is possible to suppress the occurrence of a condition in which the line oil pressure PL is inadequate, in comparison to a case of controlling the line oil pressure PL with only an independent linear solenoid valve. That is, even assuming that one among the linear solenoid valves SLS and SLT has failed, the line oil pressure PL will be controlled by the other linear solenoid valve, so it is possible to suppress the occurrence of a condition in which the line oil pressure PL is inadequate, and thus it is possible to appropriately control the line oil pressure PL. Thus, even on a low gear side where the gear ratio γ of the belt-driven continuously variable transmission 40 is large, it is possible to secure the clamping oil pressure POUT necessary for belt clamping, and so it is possible to suppress the occurrence of belt slippage.

Also, when controlling engagement/release of the lockup clutch 26 with the linear solenoid valve SLT, regulation of the line oil pressure PL is controlled with the linear solenoid valve SLS, so it is possible to suppress the occurrence of a condition in which the line oil pressure is not adjusted or a condition in which the line oil pressure is inadequate, and thus it is possible to appropriately control the line oil pressure.

Here, as described above, when the gear ratio γ is higher than γ1 (see FIG. 4), it is preferable to set the line oil pressure PL to be the same as or slightly higher than the target clamping oil pressure, and in this case, by controlling regulation of the line oil pressure PL based on the control oil pressure PSLS of the linear solenoid valve SLS, it is possible to suppress driving failure of the oil pump 27. On the other hand when the gear ratio γ is lower than γ1, it is preferable to set the line oil pressure PL to be the same as or slightly higher than the target gearshift oil pressure, and in this case, by controlling regulation of the line oil pressure PL based on the control oil pressure PSLT of the linear solenoid valve SLT, it is possible to suppress driving failure of the oil pump 27.

Above, an embodiment of the invention was described, but the embodiment described here is an example, and various modifications are possible.

In the above embodiment, a case was described in which the control oil pressure PSLT of the linear solenoid valve SLT is supplied to the primary regulator valve 110 via the switching valve 150, but as shown in FIG. 6, a configuration may also be adopted in which the control oil pressure PSLT of the linear solenoid valve SLT is supplied to the primary regulator valve 110 directly. In this case, a switching valve 220 is provided between the linear solenoid valve SLT and the lockup control valve 140. FIG. 6 shows only a part of an oil pressure control circuit 100″, but except for the configuration in the vicinity of the switching valve 220, the configuration is the same as the oil pressure control circuit 100 shown in FIG. 3.

Next is a description of the oil pressure control circuit 100″ shown in FIG. 6.

The primary regulator valve 110 has the same configuration as in the above embodiment. The control port 115 c of the primary regulator valve 110 is connected to the output port SLTb of the linear solenoid valve SLT via an oil path 103″. The control oil pressure PSLT of the linear solenoid valve SLT is supplied to the control oil pressure chamber 113 c via this control port 115 c. That is, the above control oil pressure PSLT is always supplied to the control oil pressure chamber 113 c of the primary regulator valve 110.

The switching valve 220 switches the oil pressure supplied to the lockup control valve 140 to either one of the control oil pressure PSLT of the linear solenoid valve SLT and the control oil pressure of the ON-OFF solenoid valve SL2. The switching valve 220 is configured to be capable of switching between the ON position shown in the left half in FIG. 6 and the OFF position shown in the right half in FIG. 6 by controlling the control oil pressure of the ON-OFF solenoid valve SL2.

The switching valve 220 is provided with a spool 221 that is movable in the axial direction and a spring 222 that serves as a biasing means that biases the spool 221 in one direction. In FIG. 6, the spool 221 is slidable in the vertical direction. The spring 222 is disposed in a compressed state in a spring chamber 224 provided on one end side of the spool 221 (the lower end side in FIG. 6). With biasing force of the spring 222, the spool 221 is pressed against in the direction (the upper direction in FIG. 6) that the switching valve 220 is held in the above-described OFF position. The switching valve 220 is provided with a control port 225, input ports 226 a and 226 b, and an output port 227.

The control port 225 is connected to a control oil pressure chamber 223 provided on the other end side (the upper end side in FIG. 6) of the spool 221. Also, the control port 225 is connected to the output port SL2 b of the ON-OFF solenoid valve SL2. Control oil pressure of the ON-OFF solenoid valve SL2 is supplied to the control oil pressure chamber 223 via the control port 225.

The input port 226 a is connected to the output port SLTb of the linear solenoid valve SLT via the oil path 103″. The control oil pressure PSLT of the linear solenoid valve SLT is input via the input port 226 a. Also, the input port 226 b is connected to the output port SL2 b of the ON-OFF solenoid valve SL2. Control oil pressure of the ON-OFF solenoid valve SL2 is input via the input port 226 b. The output port 227 is connected to the control port 145 a of the lockup control valve 140 via an oil path 104″.

The switching operation of the switching valve 220 is controlled by the ON-OFF solenoid valve SL2. The ON-OFF solenoid valve SL2 is controlled to the OFF state when performing engagement/release of the lockup clutch 26 (during an engagement/release operation of the lockup clutch 26). In this case, supply of the control oil pressure of the ON-OFF solenoid valve SL2 to the control oil pressure chamber 223 is stopped, so the switching valve 220 is held in the OFF position. Thus, the input port 226 a and the output port 227 are in communication. Due to the input port 226 a and the output port 227 being in communication, the control oil pressure PSLT of the linear solenoid valve SLT is supplied to the control oil pressure chamber 143 of the lockup control valve 140.

On the other hand, the ON-OFF solenoid valve SL2 is controlled to the ON state when not performing engagement/release of the lockup clutch 26 (when the lockup clutch 26 is in a state of complete engagement or complete release). Along with this, control oil pressure of the ON-OFF solenoid valve SL2 is introduced to the control oil pressure chamber 223 via the control port 225, and thus the switching valve 220 is held in the ON position. Thus, the input port 226 b and the output port 227 are in communication. Due to the input port 226 b and the output port 227 being in communication, the control oil pressure of the ON-OFF solenoid valve SL2 is supplied to the control oil pressure chamber 143 of the lockup control valve 140.

Accordingly, when the switching valve 220 is being held in the OFF position, the control oil pressure PSLT is introduced to the control oil pressure chamber 143, and engagement/release of the lockup clutch 26 is controlled based on this control oil pressure PSLT. On the other hand, when the switching valve 220 is being held in the ON position, the control oil pressure of the ON-OFF solenoid valve SL2 is introduced to the control oil pressure chamber 143 of the lockup control valve 140, and in this case, the lockup clutch 26 is held in a completely engaged state. The control oil pressure of the ON-OFF solenoid valve SL2 is set to a pressure that is no less than the maximum value of the above control oil pressure PSLT, and that is a pressure at which it is possible to hold the lockup clutch 26 in the completely engaged state.

The present invention may be embodied in various other forms without departing from the gist or essential characteristics thereof. The embodiments disclosed in this application are to be considered in all respects as illustrative and not limiting. The scope of the invention is indicated by the appended claims rather than by the foregoing description, and all modifications or changes that come within the meaning and range of equivalency of the claims are intended to be embraced therein. 

1. An oil pressure control apparatus comprising: a belt-driven continuously variable transmission in which a belt is clamped with oil pressure to transmit motive power, and a gear ratio is changed by changing a belt contact radius; a hydraulic lockup clutch provided in a hydrodynamic power transmission apparatus provided between a motive power source and the belt-driven continuously variable transmission, the lockup clutch directly coupling the motive power source side and the belt-driven continuously variable transmission side; a line oil pressure control valve that regulates a line oil pressure that becomes a source pressure of oil pressure of various parts; and a clamping oil pressure control valve that supplies a clamping oil pressure that controls a belt clamping pressure of the belt-driven continuously variable transmission to a driven-side pulley of the belt-driven continuously variable transmission; wherein control of the line oil pressure control valve is performed with a control oil pressure of a first electromagnetic valve that controls the clamping oil pressure control valve, and a control oil pressure of a second electromagnetic valve that controls engagement/release of the lockup clutch, the apparatus further comprising: a switching means provided between the line oil pressure control valve and the second electromagnetic valve, the switching means being capable of switching between supplying the control oil pressure of the second electromagnetic valve to the line oil pressure control valve, and supplying the control oil pressure of the second electromagnetic valve to a lockup control valve that is switched when controlling engagement/release of the lockup clutch; wherein the switching means, when engaging the lockup clutch, is switched so as to supply the control oil pressure of the second electromagnetic valve to the lockup control valve, and at other times, is switched so as to supply the control oil pressure of the second electromagnetic valve to the line oil pressure control valve.
 2. The oil pressure control apparatus according to claim 1, wherein the control oil pressure of the second electromagnetic valve is always supplied to the line oil pressure control valve, and supply of the control oil pressure of the second electromagnetic valve to the lockup control valve is controlled with a third electromagnetic valve.
 3. The oil pressure control apparatus according to claim 1, wherein the line oil pressure control valve is controlled based on the higher control oil pressure among the control oil pressure of the first electromagnetic valve and the control oil pressure of the second electromagnetic valve.
 4. The oil pressure control apparatus according to claim 1, wherein an acting area of the control oil pressure of the first electromagnetic valve on a spool of the line oil pressure control valve is the same as an acting area of the control oil pressure of the second electromagnetic valve on that spool.
 5. The oil pressure control apparatus according to claim 1, wherein an acting area of the control oil pressure of the second electromagnetic valve on a spool of the line oil pressure control valve is larger than an acting area of the control oil pressure of the first electromagnetic valve on that spool.
 6. The oil pressure control apparatus according to claim 1, further comprising: a hydraulic friction engaging element for travel that is engaged in order to establish a power transmission path when a vehicle travels, wherein when controlling an engagement transition in which the friction engaging element for travel is engaged, the control oil pressure of the second electromagnetic valve is supplied to the friction engaging element for travel, and other than when controlling that engagement transition, an engagement holding oil pressure that has been regulated with another system is supplied to the friction engaging element for travel.
 7. The oil pressure control apparatus according to claim 6, wherein switching between the control oil pressure of the second electromagnetic valve that is supplied to the friction engaging element for travel, and the engagement holding oil pressure that is supplied to the friction engaging element for travel, is controlled with a fourth electromagnetic valve.
 8. An oil pressure control apparatus comprising: a belt-driven continuously variable transmission in which a belt is clamped with oil pressure to transmit motive power, and a gear ratio is changed by changing a belt contact radius; a hydraulic lockup clutch provided in a hydrodynamic power transmission apparatus provided between a motive power source and the belt-driven continuously variable transmission, the lockup clutch directly coupling the motive power source side and the belt-driven continuously variable transmission side; a hydraulic friction engaging element for travel that is engaged in order to establish a power transmission path when a vehicle travels; and a line oil pressure control valve that regulates a line oil pressure that becomes a source pressure of oil pressure of various parts; wherein control of the line oil pressure control valve, control of engagement/release of the lockup clutch, and control of engagement transition oil pressure when engaging the friction engaging element for travel, are performed with one electromagnetic valve, the apparatus further comprising: a switcher provided between the line oil pressure control valve and the second electromagnetic valve, the switcher being capable of switching between supplying the control oil pressure of the second electromagnetic valve to the line oil pressure control valve, and supplying the control oil pressure of the second electromagnetic valve to a lockup control valve that is switched when controlling engagement/release of the lockup clutch; wherein the switcher, when engaging the lockup clutch, is switched so as to supply the control oil pressure of the second electromagnetic valve to the lockup control valve, and at other times, is switched so as to supply the control oil pressure of the second electromagnetic valve to the line oil pressure control valve.
 9. The oil pressure control apparatus according to claim 8, wherein when controlling engagement/release of the lockup clutch with the electromagnetic valve, the line oil pressure control valve is controlled with another electromagnetic valve.
 10. The oil pressure control apparatus according to claim 9, wherein the other electromagnetic valve controls a clamping oil pressure control valve that supplies a clamping oil pressure that controls a belt clamping pressure of the belt-driven continuously variable transmission to a driven-side pulley of the belt-driven continuously variable transmission. 